The gene for human apolipoprotein CI is located 4.3 kilobases away from the apolipoprotein E gene on chromosome 19

Summary We have isolated a cDNA clone for apolipoprotein CI and a genomic clone for apolipoprotein E, and by hybridisation and mapping experiments found the gene for apoCI to be located on the genomic apoE clone. The distance between the loci was 4.3 kb.     

Isolation, characterization, and mapping to chromosome 19 of the human apolipoprotein E gene

The human apo-E gene has been isolated from a lambda phage library using as a probe the previously reported apo-E cDNA clone pE-301. Lambda apo-E was mapped and subcloned, and the apo-E gene was completely sequenced. The DNA sequence was compared with that of a near full length cDNA clone pE-368 and revealed three introns. The first intron was in the region that corresponds to the 5' untranslated region of apo-E mRNA. The second intron interrupted the codon specifying amino acid -4 of the apo-E signal peptide. The third intron interrupted the codon specifying amino acid 61 of the mature protein. Analysis of the DNA sequence revealed four Alu sequences. Two were in opposite orientations in the second intron, and one each occurred in the regions 5' and 3' to the apo-E gene. There were two base differences between the apo-E gene sequence and the sequence derived from the cDNA clones. At the codon for amino acid residue 112, the apo-E gene contained CGC, specifying Arg, whereas the cDNA contained TGC, specifying Cys. The other base difference was in the area corresponding to the 5' untranslated region of apo-E mRNA. Apo-E is commonly polymorphic in the population and the data suggest that the genomic clone was derived from the epsilon 4 apo-E allele, whereas the cDNA clones were derived from the epsilon 3 apo-E allele. S1 nuclease protection and primer extension experiments allowed the tentative assignment of the cap site of apo-E mRNA to the A approximately 44 base pairs upstream of the GT that begins the first intron. The sequence TATAATT was identified beginning 33 base pairs upstream of the proposed cap site and is presumably one element of the apo-E promoter. Finally, the apo-E gene was mapped in the human genome to chromosome 19 through the use of DNA probes and human-rodent somatic cell hybrids.     

Isolation and characterisation of a cDNA clone for human apolipoprotein CI and assignment of the gene to chromosome 19

Summary We have synthesised a mixed oligonucleotide 17 bases long and used it to isolate cDNA clones for apolipoprotein CI (apo CI) from an adult liver cDNA library. The partial sequence of one of these clones confirms its identity. We have used this probe and Southern blotting techniques to identify the human apo CI gene in DNA from a series of rodent x human somatic cell hybrids. Our Results provide evidence for the assignment of this gene to human chromosome 19.     

The locus for apolipoprotein E (apoE) is close to the Lutheran (Lu) blood group locus on chromosome 19

Summary Linkage has been described between the loci for apolipoprotein E (apoE) and the complement C3 (C3) on chromosome 19. C3 is known to belong to a linkage group with gene order C3-Se-Lu. The present study revealed linkage between Se and apoE with peak lod score +3.3 at recombination fraction 0.08 in males and +1.36 at 0.22 in females, and linkage between apoE and Lu with lod score +4.52 at zero recombination in sexes combined. The C3-apoE linkage gives lod score +4.00 at = 0.18 in males, but +0.04 at =0.45 in females. Triple heterozygote families confirm that apoE is on the Se side and on the Lu side of C3. Allelic association between apoE and Lu has not been ruled out. Combining our data with published data on C3-Se and Se-Lu, this segment of chromosome 19 has an average sex ratio of female/male recombination of 2.3.     

A physical map of the apolipoprotein gene cluster on human chromosome 19

Summary We have generated a restriction map around the cloned genes for human apolipoproteins CI, CII, and E by pulsed-field gel analysis. We show that the genes are clustered within an area of about 50 kb on chromosome 19. The genes are all oriented in the same direction, head to tail.     

The locus for apolipoprotein CII is closely linked to the apolipoprotein E locus on chromosome 19 in man

Summary We have demonstrated close linkage between the genes for apolipoprotein E (apoE) and apolipoprotein CII (apoCII). Families segregating for apoE protein variants were screened for a DNA restriction fragment length polymorphism close to the apoCII gene by using an apoCII cDNA clone. The maximum lod score is 4.52 (sexes combined) at a recombination frequency of zero. Given linkage, it may be assumed that no recombinations have happened in altogether 33 observed meioses. It is therefore evident that the apoCII gene is situated on chromosome 19, close to the apoE gene.     

Variation at the apolipoprotein (apo) AI-CIII-AIV gene cluster and apo B gene loci is associated with lipoprotein and apolipoprotein levels in Italian children.

We have used RFLPs of the apolipoprotein (apo) B gene and apo AI-CIII-AIV gene cluster to estimate the genetic contribution of variation at these loci to the variability of plasmid lipid, lipoprotein, and apolipoprotein levels in 209 children from Sezze in central Italy. The sample was randomly divided into group I (107 children) and group II (102 children). Four site polymorphisms (PvuII, XbaI, MspI, and EcoRI) of the apo B gene and five site polymorphisms (XmnI, PstI, SstI, PvuII-CIII, and PvuII-AIV) of the apo AI-CIII-AIV gene cluster were examined in group I children. After adjustment for gender, age, and body-mass index, polymorphisms at both gene loci (PvuII-B, PvuII-CIII, and PvuII-AIV) were associated with significant effects on the levels of plasma apo AI, apo B, or high-density lipoprotein-cholesterol. RFLPs that showed significant effects in group I were genotyped in group II. All three polymorphisms were associated with similar effects on apolipoprotein levels, though for all RFLPs the magnitude of the effects was smaller in the group II children and only statistically significant for the effect of the PvuII-B genotype on apo AI levels. In the total sample of 209 children 7.4% of the sample variance in apo AI levels was explained by variation associated with the apo B PvuII-B RFLP. In addition, the PvuII-B RFLP was associated with significant effects on plasma apo B levels and explained 5.7% of the sample variance. The PvuII-CIII and PvuII-AIV polymorphisms were both associated with differences in apo AI levels, explaining 3.7%-5.7% of the sample variance. Taken together, the three PvuII polymorphisms explained 17.7% of the phenotypic variance in apo AI levels. There was significant evidence for an effect of nonlinearity of the PvuII-CIII genotypes on apo AI levels, with the individuals heterozygous for the polymorphism having the highest apo AI levels. No evidence of interaction between genotype and gender, age, and body-mass index was shown by covariance analysis. The molecular explanation of this effect is unclear. Our data show that variation at both the apo AI-CIII-AIV and apo B loci are associated with lipoprotein and apolipoprotein levels in this sample of Italian children.     

Two copies of the human apolipoprotein C-I gene are linked closely to the apolipoprotein E gene

The gene for human apolipoprotein (apo) C-I was selected from human genomic cosmid and lambda libraries. Restriction endonuclease analysis showed that the gene for apoC-I is located 5.5 kilobases downstream of the gene for apoE. A copy of the apoC-I gene, apoC-I', is located 7.5 kilobases downstream of the apoC-I gene. Both genes contain four exons and three introns; the apoC-I gene is 4653 base pairs long, the apoC-I' gene 4387 base pairs. In each gene, the first intron is located 20 nucleotides upstream from the translation start signal; the second intron, within the codon of Gly-7 of the signal peptide region; and the third intron, within the codon for Arg39 of the mature plasma protein coding region. The upstream apoC-I gene encodes the known apoC-I plasma protein and differs from the downstream apoC-I' gene in about 9% of the exon nucleotide positions. The most important difference between the exons results in a change in the codon for Gln-2 of the signal peptide region, which introduces a translation stop signal in the downstream gene. Major sequence differences are found in the second and third introns of the apoC-I and apoC-I' genes, which contain 9 and 7.5 copies, respectively, of Alu family sequences. The apoC-I gene is expressed primarily in the liver, and it is activated when monocytes differentiate into macrophages. In contrast, no mRNA product of the apoC-I' gene can be detected in any tissue, suggesting that it may be a pseudogene. The similar structures and the proximity of the apoE and apoC-I genes suggest that they are derived from a common ancestor. Furthermore, they may be considered to be constituents of a family of seven apolipoprotein genes (apoE, -C-I, -C-II, -C-III, -A-I, -A-II, and -A-IV) that have a common evolutionary origin.     

There are two mechanisms of achiasmate segregation in Drosophila females,one of which requires heterochromatic homology

There are numerous examples of the regular segregation of achiasmate chromosomes at meiosis I in Drosophila melanogaster females. Classically, the choice of achiasmate segregational partners has been thought to be independent of homology, but rather made on the basis of availability or similarities in size and shape. To the contrary, we show here that heterochromatic homology plays a primary role in ensuring the proper segregation of achiasmate homologs. We observe that the heterochromatin of chromosome 4 functions as, or contains, a meiotic pairing site. We show that free duplications carrying the 4th chromosome pericentric heterochromatin induce high frequencies of 4th chromosome nondisjunction regardless of their size. Moreover, a duplication from which some of the 4th chromosome heterochromatin has been removed is unable to induce 4th chromosome nondisjunction. Similarly, in the absence of either euchromatic homology or a size similarity, duplications bearing the X chromosome heterochromatin also disrupt the segregation of two achiasmate X chromosome centromeres. Although heterochromatic regions are sufficient to conjoin nonexchange homologues, we confirm that the segregation of heterologous chromosomes is determined by size, shape, and availability. The meiotic mutation Axs differentiates between these two processes of achiasmate centromere coorientation by disrupting only the homology-dependent mechanism. Thus there are two different mechanisms by which achiasmate segregational partners are chosen. We propose that the absence of diplotene-diakinesis during female meiosis allows heterochromatic pairings to persist until prometaphase and thus to co-orient homologous centromeres. We also propose that heterologous disjunctions result from a separate and homology-independent process that likely occurs during prometaphase. The latter process, which may not require the physical association of segregational partners, is similar to those observed in many insects, in Saccharomyces cerevisiae and in C. elegans males. We also suggest that the physical basis of this process may reflect known properties of the Drosophila meiotic spindle. © 1993 Wiley-Liss, Inc.     

The locus for apolipoprotein E (apoE) is linked to the complement component C3 (C3) locus on chromosome 19 in man

Summary By two-dimensional electrophoresis of human serum a genetically determined polymorphism of apolipoprotein E (apoE) can be demonstrated. Three alleles occur with appreciable frequency in Caucasian populations. In the present study the segregation of apoE and complement component C3 (C3) types in material from Norwegian families has been studied. Linkage has convincingly been demonstrated between the two loci with a lod score of 3.00 in males at a recombination fraction of 13%. As it is known that the C3 locus is situated on chromosome 19 in man, apoE can be located to this specific chromosome. Positive linkage data do not, to our knowledge, at present exist with regard to other apolipoproteins.     

Polymorphisms in the apolipoprotein (apo) AI-CIII-AIV gene cluster: detection of genetic variation determining plasma apo AI,apo CIII and apo AIV concentrations

We have examined the associations between levels of plasma apolipoprotein (apo) AI, apo CIII and apo AIV and genetic variation in the apo AI-CIII-AIV gene cluster in 162 boys and young men from Belgium aged from 7 to 23 years. Genotypes were determined for six restriction enzymes XmnI, PstI, SstI, PvuIIA-CIII, PvuIIB-AIV and XbaI, and for the G to A substitution at -75 bp in the 5' region of the apo AI gene. The polymorphism most strongly associated with apo AI levels was the G to A substitution (P = 0.025, R2 x 100 = 3.6%) confirming previous observations. The polymorphism most strongly associated with apo CIII levels was that of PvuIIA-CIII (P = 0.023, R2 x 100 = 2.9%) in the apo CIII gene. This novel association must be interpreted with caution until it has been confirmed in an independent sample. The polymorphism associated with the largest effect on apo AIV levels was that detected with XbaI in the apo AIV gene, but this association was not statistically significant. Previously reported associations between the SstI polymorphism and triglyceride levels, and between the PstI polymorphism and apo AI levels, were weakly detected in the present sample. Our results show that variation associated with some of the polymorphisms in the apo AI-CIII-AIV cluster makes a small, but statistically significant, contribution to the determination of apo AI and apo CIII levels in this sample of young men and boys. These observations may, in part, explain reported associations between polymorphisms in this gene cluster, differences in plasma lipid and lipoprotein levels, and prevalence of coronary artery disease.     

There are two mechanisms of achiasmate segregation in Drosophila females, one of which requires heterochromatic homology.

There are numerous examples of the regular segregation of achiasmate chromosomes at meiosis I in Drosophila melanogaster females. Classically, the choice of achiasmate segregational partners has been thought to be independent of homology, but rather made on the basis of availability or similarities in size and shape. To the contrary, we show here that heterochromatic homology plays a primary role in ensuring the proper segregation of achiasmate homologs. We observe that the heterochromatin of chromosome 4 functions as, or contains, a meiotic pairing site. We show that free duplications carrying the 4th chromosome pericentric heterochromatin induce high frequencies of 4th chromosome nondisjunction regardless of their size. Moreover, a duplication from which some of the 4th chromosome heterochromatin has been removed is unable to induce 4th chromosome nondisjunction. Similarly, in the absence of either euchromatic homology or a size similarity, duplications bearing the X chromosome heterochromatin also disrupt the segregation of two achiasmate X chromosome centromeres. Although heterochromatic regions are sufficient to conjoin nonexchange homologues, we confirm that the segregation of heterologous chromosomes is determined by size, shape, and availability. The meiotic mutation Axs differentiates between these two processes of achiasmate centromere coorientation by disrupting only the homology-dependent mechanism. Thus there are two different mechanisms by which achiasmate segregational partners are chosen. We propose that the absence of diplotene-diakinesis during female meiosis allows heterochromatic pairings to persist until prometaphase and thus to co-orient homologous centromeres. We also propose that heterologous disjunctions result from a separate and homology-independent process that likely occurs during prometaphase. The latter process, which may not require the physical association of segregational partners, is similar to those observed in many insects, in Saccharomyces cerevisiae and in C. elegans males. We also suggest that the physical basis of this process may reflect known properties of the Drosophila meiotic spindle.     

Linkage relationships of the gene for apolipoprotein CII with loci on chromosome 19

Two common restriction fragment length polymorphisms detected with cloned gene probes for apolipoprotein CII (apo CII) have been used to study the inheritance of the gene in families segregating for loci on chromosome 19. Lod scores for APOC2 with the gene for complement component 3 (C3) exclude close linkage and give a maximum at a male recombination fraction of 0.25-0.30. Lod scores for APOC2 and FHC, the gene causing familial hypercholesterolaemia, are negative in males and suggest the genes may not be linked. However, it appears that APOC2 may be closely linked to the blood group loci Lutheran (Lu) and Secretor (Se), and probably less closely linked to Lewis (Le). These data are consistent with the gene order: FHC-----C3-----(Lu, Se, APOC2)     

The human cystatin C gene (CST3) is a member of the cystatin gene family which is localized on chromosome 20

The fourth gene from the human cystatin gene family of salivary-type cysteine-proteinase inhibitors has been isolated and partially characterized by DNA analysis. The gene, which we name CST3, codes for human cystatin C, and has the same organization as the CST1 gene for cystatin SN and the CST2 gene for cystatin SA. Southern analysis of EcoR I digested DNAs from 32 independent somatic cell hybrid clones hybridized to a probe from CST1 demonstrated that all members of the cystatin gene family segregate with human chromosome 20. These results indicate that the genes for salivary-type cystatins and cystatin C are members of a multigene family--the cystatin gene family.     

An expressed beta-tubulin gene, TUBB, is located on the short arm of human chromosome 6 and two related sequences are dispersed on chromosomes 8 and 13

The chromosomal assignments of an expressed beta-tubulin gene and two related sequences have been determined by Southern blot analysis of DNA from a panel of human x Chinese hamster somatic cell hybrids cleaved with Hind III or EcoRI. Probes containing the 3' untranslated regions of the expressed gene M40 and of pseudogene 21 beta were used to localize the M40 sequence (gene symbol TUBB) to chromosome 6 region 6p21----6pter, the 21 beta pseudogene (TUBBP1) to chromosome 8 region 8q21----8pter and a third related sequence (TUBBP2) to chromosome 13. Asynteny of expressed genes and related processed pseudogenes has now been demonstrated for several gene families.     

Identification of human apolipoprotein E variant gene: apolipoprotein E7 (Glu244,245----Lys244,245)

Apolipoprotein E (apoE) is one of the protein moieties of the human serum lipoproteins. Three major isoforms of apoE (apoE2, apoE3, and apoE4) and minor variant isoforms (apoE1, apoE5, and apoE7) have been detected by isoelectric focusing. In this study we have cloned the apoE7 gene from a patient with the apoE3/E7 phenotype associated with hypertriglyceridemia and diabetes mellitus. DNA sequencing revealed that the apoE7 gene has two base substitutions (G----A) changing Glu244,245----Lys244,245, compared with the apoE3 gene. The replacement of the two amino acids is consistent with the result of isoelectric focusing of the apoE7 isoprotein, which shifts to four positively charged units compared with the apoE3 isoprotein.